RU2198468C2 - Method and device for synchronizing states of base and mobile stations in code-division multiple access communication system - Google Patents

Abstract

FIELD: burst data transmission in mobile code-division multiple access system. SUBSTANCE: first method involves transmission of state check message from base station to mobile station in active state. Base station receives response message from mobile station and analyzes response message received to determine mobile station state. Base station terminates operation of respective channel and turns to mobile station state. Second method involves transmission of state check message from base station to mobile station during burst data transmission between base and mobile stations in mobile CDMA communication system in active state. Mobile station receives response message from base station and analyzes received response message to determine state of base station. Mobile station terminates operation of respective channel and turns to base station state. In this way proposed methods alternately synchronize base and mobile stations according to servicing conditions or according to predetermined states of system. EFFECT: reduced signaling charges, consumption of radio resources and synchronization time. 6 cl, 6 dwg

Description

 The invention relates to a mobile communication system and, in particular, to a method for synchronizing states between a base station and a mobile station with reduced signaling overhead during packet data transmission on a transmission medium access control (MAC) sublayer in a code division multiple access mobile communication system channels (CDMA).

State of the art
Mobile communication systems provide a circuit-switched service and a packet data service. In the case of a packet data service, signaling messages are often generated and compared with a circuit switched service. Packet data has a “pulsed” property, that is, they are formed intermittently. Therefore, a dedicated traffic channel and a dedicated control channel are assigned intermittently to all users during the service period, taking into account the following factors: the capacity of radio resources for a mobile communication system, the functionality of a base station for serving all users, and the power consumption of a mobile station.

 Dedicated channels are allocated during the presence of traffic. If a predetermined period of time expires after packet data, the dedicated channels terminate so that other users can use these resources. That is, the channels are distributed dynamically. In a system providing a packet data service, the states of the base station and the mobile station undergo changes depending on whether data is generated, and therefore, the appearance of signaling messages between the base station and the mobile station is common. Therefore, it is important to maintain synchronization between the base station and the mobile station.

 In a conventional CDMA mobile communication system, a circuit-switched service is mainly provided for synchronizing a base station with a mobile station. Most signaling messages used in a conventional system are designed to handle call setup, handoff, and call termination and are generated at level three. After transmitting the signaling message from the base station to the mobile station, a command is transmitted over the forward link, and the mobile station receiving the command transmits a response to the base station. The base station again transmits a confirmation message to inform the mobile station that the command is normally processed. Moreover, after transmitting the signaling message from the mobile station to the base station, a request is transmitted on the reverse link, and the base station receiving the request transmits a response to the mobile station.

 The transmission of signaling messages on the forward and reverse links between the base station and the mobile station is defined as the overhead of signaling the communication system.

 1A and 1B, respectively, illustrate conventional signaling message transmission methods when the base station (BS) informs the mobile station (MS) of the occurrence of the event, and when the mobile station (MS) informs the base station (BS) of the occurrence of the event. These signaling message transfer methods are used to process Layer 3 signaling messages generated during call setup, handover, and call termination. However, since in the above procedures, signaling messages are transmitted and received one after another, many radio resources are used, and the signaling overhead is increased, and therefore, it takes some time to maintain synchronization between the base station and the mobile station. Accordingly, system performance and efficiency are reduced.

SUMMARY OF THE INVENTION
An object of the present invention is to provide a method for reducing signaling overhead in order to maintain synchronization between a base station and a mobile station in a sub-layer of a UDS of a mobile communication system having a packet data service that is subject to frequent state changes.

 Another objective of the present invention is to provide a method for reducing unnecessary consumption of radio resources and synchronization time by alternately performing synchronization between the base station and the mobile station in accordance with the service conditions or predetermined system conditions.

 In order to achieve the solution of the above problems, the present invention provides a state synchronization method for packet data transmission between a base station and a mobile station in a CDMA mobile communication system. The method includes the following steps: transmitting from the base station a status check message to the mobile station in an active state; receiving at the base station a response message from the mobile station; and analyzing the received response message to determine the state of the mobile station, shutting down the corresponding channel, and transferring the base station to the state of the mobile station.

 According to the present invention, if the mobile station is in an active state, the base station maintains an active state; if the mobile station is in a control hold state, the base station shuts down the dedicated traffic channel to transition to a control hold state; if the mobile station is in a suspended state, the base station shuts down the dedicated traffic channel to enter the control hold state, and then shuts down the dedicated control channel to transition to the suspended state, and if the mobile station is not in any of the following states: active, control hold state and paused state, the base station terminates the dedicated traffic channel to enter the control hold state and terminates t dedicated control channel operation to switch to the suspended state, and terminates a common control channel operation for transition to the inactive state.

 The present invention further provides a state synchronization method for packet data transmission between a base station and a mobile station in a CDMA mobile communication system. The method includes the following steps: transmitting a status check message to the base station in the active state at the mobile station; receiving in the mobile station a response message from the base station; and analyzing the received response message to determine the state of the base station, shutting down the corresponding channel, and transferring the mobile station to the state of the base station.

 If the base station is in an active state, the mobile station maintains an active state; if the base station is in a control hold state, the mobile station terminates the dedicated traffic channel to enter the control hold state; if the base station is in a paused state, the mobile station terminates the dedicated traffic channel to transition to the hold state of control, and then terminates the dedicated control channel to transition to the suspended state; and if the base station is not in any of the listed states — active, control hold state, and suspended state, the mobile station terminates the dedicated traffic channel to enter the control hold state, terminates the dedicated control channel to transition to the suspended state, and shuts down a common control channel to go into an inactive state.

Brief Description of the Drawings
The above and other objectives, features and advantages of the present invention are explained in the following detailed description, illustrated by drawings, which show the following:
figa - a known method of transmitting signaling messages when the base station informs the mobile station of the occurrence of an event;
FIG. 1B is a known method for transmitting alarm messages when a mobile station informs a base station of an event;
FIG. 2A is a method for re-initializing a state timer used for a direct supplemental channel according to an embodiment of the present invention;
FIG. 2B is a method for re-initializing a state timer used for a reverse supplemental channel according to an embodiment of the present invention;
FIG. 3 illustrates a method for transitioning from an active state to a control holding state using a state timer according to an embodiment of the present invention;
4 is a flowchart illustrating a state synchronization method performed by a base station having a state timer and a watchdog timer for transmitting packet data with a mobile station according to an embodiment of the present invention;
5 is a flowchart illustrating a state synchronization method executed by a base station generating a state change command including a response request field for packet data transmission with a mobile station according to an embodiment of the present invention; and
6 is a flowchart illustrating a state synchronization method performed by a mobile station for transmitting packet data with a base station generating a state change command including a response request field according to an embodiment of the present invention.

Detailed Description of Preferred Embodiments
A preferred embodiment of the present invention is described below with reference to the drawings. In the following description, numerous specific details are set forth in order to provide a more thorough understanding of the present invention. One skilled in the art, however, will appreciate that the present invention may be practiced without these details. In addition, well-known constructions or functions are not described in detail so as not to complicate the understanding of the present invention.

 The present invention uses a status timer or a monitoring timer in addition to transmitting known signaling messages during the monitoring period, that is, when monitoring time is running to maintain synchronization between the base station and the mobile station. The base station and the mobile station can both be equipped with these timers, or only one of them can be equipped with this timer. The synchronization method between the base station and the mobile station is different in accordance with the conditions of service (for example, the conditions of stable radio communication, for example indoors, or the conditions for slow or fast movement of the mobile station). When using signaling messages, only a command message can be used, or both a command message and a response message can be used in accordance with the service conditions to reduce signaling overhead.

 The state timer checks the time from the current state to the next state, and the watchdog timer checks for inconsistent states. Therefore, if these two timers are used, a state change is possible without signaling messages, and state inconsistency can easily be checked.

 A state synchronization method using timers is divided into three types: a distributed type in which the base station and the mobile station each have a state timer and a monitoring timer, a type with a leading base station in which the base station has a state timer and a monitoring timer, and the mobile station has only a watchdog timer, and a type with a leading mobile station, in which the base station has only a watchdog timer, and the mobile station has a status timer and watchdog timer.

 A distributed type that does not use signaling messages does not create overhead for signaling, but if there is a failure in either the base station or the mobile station, there may be a state inconsistency. In the case of a leading base station or a leading mobile station, a signaling message should be transmitted to the mobile station or base station, respectively, if there is a state change at the time the status timer expires, thereby using a plurality of radio resources compared to the distributed type. This creates overhead for signaling and lengthens the time synchronization of states.

 According to the present invention, signaling overhead can be reduced by including a response request field in a command message, in contrast to the conventional method in which a response message is transmitted after receiving a command message. Namely, if the rate of occurrence of erroneous frames (FER) exceeds a threshold value, then this response request field is set and a response request message is transmitted. The party receiving the command message then transmits a response message. If other radio conditions are stable, then only a command message is transmitted. Since the value of the FER is large when the mobile station moves quickly or crosses an area where there is strong radio interference, it is preferable to use signaling messages and timers for reliable state synchronization. Since the packet data service under stable radio conditions has a low probability of creating a state inconsistency caused by a handover, it is possible to maintain synchronization between the base station and the mobile station using a timer. That is, if the watchdog timer expires, it is determined that there is a state inconsistency, and a signaling message is used to maintain synchronization. Here, if the FER is greater than the threshold value, a command message is transmitted including a response request field indicating a request for a response message.

FIG. 2A and 2B illustrate methods for re-initializing a state timer applied respectively to the forward supplemental channel and the reverse supplemental channel. The active state timer T _{active is} reinitialized by packet data when the control hold state changes to an active state, provided that the base station and the mobile station each have a state timer. The arrows shown by the solid line determine the transmission time of the radio frame of the base station, and the arrows indicated by the dotted line determine the transmission time of the radio frame of the mobile station. Since the mobile station maintains synchronization with information transmitted from the base station, there is a slight delay. In other words, the transmission time of the radio frames of the mobile station lags behind the transmission time of the radio frames of the base station in time. Therefore, the arrows corresponding to the mobile station are not aligned with the arrows corresponding to the base station.

If the base station (FIG. 2A) transmits traffic at the time of transmitting the radio frame, the mobile station receives traffic with a prescribed propagation delay. The base station re-initializes the _active active timer T after completion of data transmission to the mobile station, and the mobile station also re-initializes the _active active timer T after completion of data reception. If the mobile station (FIG. 2B) transmits traffic at the time of transmission of the radio frame, the base station receives traffic with a prescribed propagation delay. The mobile station reinitializes the _active active timer T after completion of data transmission to the base station, and the base station also reinitializes the _active active timer T after completion of data reception.

FIG. 3 illustrates the process of transition from an active state to a hold state using a state timer. The transition from the active state to the control hold state occurs when the timer T _active active state expires. Similarly, a transition from a control hold state to a paused state occurs when the timer T _{hold of} control hold in the normal case expires. If the active state timer T _active expires without transmitting a packet for a prescribed period of time in the active station, then the dedicated BKT traffic channel ends, the active state changes to the control _hold state and the control _hold state timer T _hold starts. The control _hold state timer T _{hold is} used to check the transition time to the paused station state. The term "state timer" described with reference to other drawings, in addition to figure 3, denotes a timer T _active active state.

 4 is a flowchart illustrating a state synchronization method performed by a base station having a state timer and a monitoring timer for packet data transmission with a mobile station.

The base station starts the watchdog timer T _watch in the active state. The _{watch watchdog} T _watch monitors if there is an inconsistency between the base station and the mobile station. If available, the base station restores state consistency. If the state is synchronous, the base station converts the data access control service unit (UDC UDS) data unit transmitted from a higher level to the medium access control protocol (UAC UDS) data block and transmits the UDS UDS to a lower level. The base station converts the BDS UDS transmitted from the lower level to the BDS UDC and transmits the BDS UDC to a higher level. A detailed description of this process is given with reference to FIG.

The base station starts the state timer T _active and the watchdog timer T _watch in the active state and proceeds to the data exchange sub-state (hereinafter referred to as the Data_change state), in which data can be exchanged (steps A1-A3). If the UDC BDS or the UDS BDP is received from a higher level or a lower level (step A4 or A10), the base station stops controlling the T _active state timer and converts the received UDC BDS to the UDS BDP and UDS BDP into the UDC BDS (steps A5, A6, A11 and A12). The base station transmits the converted data to a lower level or a higher level, starts the Tactive state timer again, and returns to the Data_ Exchange state (steps A7-A9 and A13-A15).

If the timer of the _active state timer T expires in the Exchange_data state, the base station terminates the dedicated BTC traffic channel, stops the monitoring timer T _watch, and enters the control hold state (steps A16-A19).

If the watchdog signal is received in the Data Exchange state, the base station transmits a status check message to the mobile station (steps A20 and A21). The mobile station receiving the status check message transmits a response message to inform the base station of its current state. If a decision is made based on the response message that the mobile station is in an active state, the base station returns to the Data_ Exchange state (steps A22 and A27). If the mobile station is not in an active state, the base station checks whether the mobile station is in a hold control state (steps A22 and A23). If yes, the base station terminates the dedicated BKT traffic channel, stops the watchdog timer T _watch, and enters the control hold state (steps A23-A26).

If the mobile station is not in a hold state, the base station checks whether the mobile station is in a suspended state (steps A23 and A28). If yes, then the base station terminates the dedicated BKT traffic channel, stops the watchdog timer T _watch, and enters the control hold state (steps A28-A31). The base station then shuts down the dedicated control channel (for example, the dedicated UDS, VKD channel) and goes into a suspended state (steps A32 and A33).

If the mobile station is not in a suspended state, the base station terminates the dedicated BKT traffic channel, stops the watchdog timer T _watch, and enters the control hold state (steps A34-A36). The base station then terminates the dedicated UDS (VCD) channel, switches to a paused state, terminates the UDS common channel (OKD), and goes into an inactive state (steps A37-A40).

Thus, the present invention provides methods for periodically checking inconsistencies of states using a watchdog timer T _watch , and for quickly shutting down the corresponding channel, thereby effectively utilizing radio resources.

 FIG. 5 is a flowchart illustrating a state synchronization method executed by a base station generating a state change command including a response request field for packet data transmission with a mobile station.

The base station has a state timer T _active , wherein a state change command is generated when the timer state T _active expires.

The base station starts the timer T _active state in the active state and proceeds to the state Data_ exchange in which data can be exchanged (steps B1-B3). The base station receives the UDC or BDP UDS from a higher level or lower level (step B4 or B10), the base station stops the T _active state timer and converts the received UDC BDS to UDS BDP and UDS BDS into UDC BDS (steps B5, B6, B11 and B12). The base station transmits the converted data to a lower level or a higher level, starts the state timer T _active again, and returns to the Data_change state (steps B7-B9 and B13-B15).

If the timer T of the _active state expires in the Exchange_data state, the base station compares the error rate of the frames (FER) with a threshold value of FER (thresholds B16 and B17). If the FER is greater than the FER threshold, the base station transmits a state change command to the mobile station with the response request field set and awaits a response from the mobile station (steps B21 and B22). The base station receives a response from the mobile station, transmits a confirmation message to the mobile station, terminates the dedicated BTC traffic channel, and transitions to the hold control state (steps B23, B24, B19 and B20). If the CHOK is not greater than the threshold value, the base station transmits a state change command to the mobile station with the reset value of the response request field, terminates the operation of the dedicated CGT traffic channel, and enters the control hold state (steps B17-B20). After receiving data from a higher level or lower level in a suspended state of waiting for a response (steps B25 and B26), the base station stops the state timer T _active (steps B11 and B5) to convert the received data.

 FIG. 6 is a flowchart illustrating a state synchronization method performed by a mobile station for packet data transmission with a base station generating a state change command including a response request field.

 After receiving the state change command from the base station in the active state, the mobile station checks whether the response request field has been set (steps C1-C3). If the response request field has not been set, the mobile station terminates the dedicated CGT traffic channel and enters the control hold state (steps C7 and C8). If the response request field has been set, the mobile station transmits a response to the base station and awaits a confirmation message (steps C4 and C5). After receiving a confirmation message from the base station, the mobile station terminates the dedicated CGT traffic channel and enters the control hold state (steps C6-C8).

 In state synchronization methods using signaling messages, as shown in FIGS. 5 and 6, it is possible to determine whether a response can be requested using a simple command message or a command message including a response request message according to radio conditions. Therefore, the efficiency of using radio conditions is increasing. That is, under stable radio conditions, the response request field is not set to omit the response and confirmation steps (C4-C6 in FIG. 6), and thus quickly complete the completion of the corresponding channel and change the state. In addition, in radio conditions with high FER, the response request field is set to increase the reliability of the system.

 As described above, in the UDS sublayer of a mobile communication system that provides packet data experiencing frequent state changes, a response request field is included in the state change command generated from the base station. The response and confirmation steps may be omitted depending on whether or not the response request field has been set. Therefore, the overhead of signaling is minimized, and state synchronization between the base station and the mobile station is maintained. You can also quickly check for inconsistent states using a watchdog timer, and therefore, the efficiency of using radio resources is further increased.

 Although the invention has been illustrated and described with respect to some preferred embodiment, it will be appreciated by those skilled in the art that various changes in form and detail can be made without changing the scope and spirit of the invention, as defined in the appended claims.

Claims (6)

 1. The method of state synchronization for packet data between the base station and the mobile station in a code division multiple access (CDMA) mobile communication system, comprising the steps of transmitting from the base station a status check message to the mobile station in the monitoring period in the active state , receive at the base station a response message from the mobile station, and transfer the state of the base station to the state of the mobile station for synchronization by analyzing the received response message Eden.  2. The state synchronization method according to claim 1, characterized in that if the mobile station is in the active state, the base station maintains an active state, if the mobile station is in the control hold state, the base station terminates the dedicated traffic channel to enter the hold state control, if the mobile station is in a suspended state, the base station shuts down the dedicated traffic channel to enter the control hold state and then shuts down you a shared control channel to go into a suspended state, and if the mobile station is not in one of the indicated states — active, control hold state and suspended state, the base station shuts down the dedicated traffic channel to go to the control hold state, terminates the dedicated control channel for transition to a suspended state and shuts down the common control channel for transition to an inactive state.  3. A method for synchronizing states for packet data transmission between a base station and a mobile station in a CDMA mobile communication system, comprising the steps of transmitting a status check message to the mobile station in the mobile station during the monitoring period in the active state, receiving a response message from the mobile station from the base station and put the mobile station in the state of the base station for synchronization by analyzing the received response message.  4. The state synchronization method according to claim 3, characterized in that if the base station is in an active state, the mobile station maintains an active state, if the base station is in a control hold state, the mobile station terminates the dedicated traffic channel to enter the hold state control, if the base station is in a suspended state, the mobile station shuts down the dedicated traffic channel to enter the control hold state and then shuts down you a shared control channel to go into a suspended state and, if the base station is not in one of the indicated states - active, control hold state and suspended state, the mobile station terminates the dedicated traffic channel to enter the control hold state and terminates the dedicated control channel for transition to a suspended state and shuts down the common control channel for transition to an inactive state.  5. A state synchronization method for packet data transmission between a base station that generates a state change command including a response request field and a mobile station in a CDMA mobile communication system, comprising the steps of checking the error rate in the base station during the period state changes in the active state, if the rate of occurrence of erroneous frames is greater than the threshold value, a state change command is transmitted from the base station with the request field set from eta to the mobile station, transfer the state of the base station to the state of the mobile station for synchronization by analyzing the received response message, and if the error rate of the frames is less than the threshold value, the state change command is sent from the base station with the reset response request field to the mobile station base station state to mobile station state for synchronization.  6. A state synchronization method for packet data transmission between a base station that generates a state change command including a response request field and a mobile station in a CDMA mobile communication system, comprising the steps of receiving a state change command from a base station in a mobile station in the active state, it is determined in the mobile station whether the response request field was set by the received state change command, if the response request field was not set, the mobile station is transferred in the state of the base station for synchronization, and if the response request field has been set, then send a response message to the base station and put the mobile station in the state of the base station for synchronization by analyzing the received verification message.

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